While no LAB (less than 102 cfu/g)

While no LAB (less than 102 cfu/g) were detected at Day 0 (Fig. 1b), mesophilic aerobic bacteria were detected in low numbers on PC agar. These were most likely contaminating Gram-positive and Gram-negative soil bacteria. The high cfu/g detected on PC agar after Day 0 were most likely LAB able to grow in the presence of oxygen. The identification of species isolated from PC agar (as shown in Fig. 1b) supports this view.

Based on colony morphology, about 260 isolates were picked from different agar plates at different stages of fermentation. Of these, we selected 27 isolates and identified them by 16S rDNA sequencing. Two isolates picked from PC agar plates at Day 0 were identified as Pseudomonas lurida and Rhodococcus fascians, respectively. Of 18 isolates picked from PC, MRS and MRS-P plates, 13 were identified as Leuconostoc mesenteroides subsp. mesenteroides and the remaining five as Enterococcus faecium. At Week 2, of seven isolates from PC and MRS plates, four were identified as E. faecium, two as Ln. mesenteroides subsp. mesenteroides, and one as Pediococcus pentosaceus. Although only a very limited number of isolates was identified, it appears that a rather normal spontaneous fermentation was achieved, with heterofermentative LAB (Ln. mesenteroides subsp. mesenteroides) dominating the early and homofermentative LAB (E. faecium) dominating the later phase of fermentation ( Lu, Breidt, Plengvidhya, & Fleming, 2003). No yeasts, moulds and enterobacteria were detected in the end products indicating good hygienic quality of the experiment carried out.

3.3. Extraction procedure and analytical methods

The extraction procedure for glucosinolates was adopted from that of Francisco et al. and modified by increasing the number of repetitions from one time to three times and decreasing the stirring time from 30 to 15 min (3 × 5 min). With three repetitions the complete extraction of all glucosinolates was possible and there was no glucosinolate found in the fourth extraction. In addition, the small modification at the end of the extraction step, by diluting the dry mass with eluent A (0.05% aqueous TFA) instead of pure water makes the peak separation and peak shapes better. For the extraction of volatiles such as I3A, the fresh sample was placed into boiling water to stop myrosinase activity (further), then the samples were homogenised. Homogenisation of the sample increased the efficiency of extraction compared to direct extraction. The selection of extraction solvent also plays an important role, as dichloromethane extracts more analytes than diethyl ether and ethyl acetate (results are not shown). The number of extraction times with dichloromethane was controlled with GC–MS. It was found that after four repetitions there was no glucosinolate degradation product left in the mother liquid.

The HPLC and GC methods were specifically developed to profile all the polar, non-polar, volatile and non-volatile degradation compounds. The long HPLC method of 60 min with acidified eluent A (0.05% TFA) leads to specific separation of glucosinolates with better peak shapes at low wavelength (227 nm). All the analytes which are identified and quantified with HPLC, in addition to the I3A, which was measured by GC, were reported in this manuscript. However, due to the huge amount of data the complete analysis of the other volatile degradation products such as iberin, allylisothiocyanate, sulforaphane and their corresponding nitriles will be communicated soon in another manuscript.